Faculty Bibliography

The function of the 12 positive charges in the 53-residue III/IV interdomain linker of the cardiac Na(+) channel is unclear. We have identified a four-generation family, including 17 gene carriers with long QT syndrome, Brugada syndrome, and conduction system disease with deletion of lysine 1500 (DeltaK1500) within the linker. Three family members died suddenly. We have examined the functional consequences of this mutation by measuring whole-cell and single-channel currents in 293-EBNA cells expressing the wild-type and DeltaK1500 mutant channel. The mutation shifted V(1/2)h( infinity ) to more negative membrane potentials and increased k(h) consistent with a reduction of inactivation valence of 1. The shift in h( infinity ) was the result of an increase in closed-state inactivation rate (11-fold at -100 mV). V(1/2)m was shifted to more positive potentials, and k(m) was doubled in the DeltaK1500 mutant. To determine whether the positive charge deletion was the basis for the gating changes, we performed the mutations K1500Q and K1500E (change in charge, -1 and -2, respectively). For both mutations, V(1/2)h was shifted back toward control; however, V(1/2)m shifted progressively to more positive potentials. The late component of Na(+) current was increased in the DeltaK1500 mutant channel. These changes can account for the complex phenotype in this kindred and point to an important role of the III/IV linker in channel activation

Brugada syndrome is an arrhythmogenic disease, characterized by syncope and sudden cardiac death, with a typical electrocardiographic pattern: right bundle branch block and ST segment elevation in the right precordial leads. Only recently, the first gene causing Brugada syndrome has been demonstrated by the identification of mutations in SCN5A, the gene encoding for the cardiac sodium channel, also responsible for the LQT3 subtype of long QT syndrome. Despite the knowledge on Brugada syndrome has dramatically improved in the recent years, the clinical management is still often empirical and limited by the lack of pharmacological therapies. Therefore, the implantable cardioverter-defibrillator (ICD) is the only life-saving option for high-risk patients. However, life-long implant in young individuals may have a major impact on the quality of life and it is not free from complications. Therefore, the identification of a robust risk stratification algorithm is of outmost importance to limit the use of ICD to the higher risk individuals. Programmed electrical stimulation has been proposed but this approach appears to have a low positive predictive value, thus leading to implants in many asymptomatic patients. Recently, we analyzed data from 200 Brugada syndrome patients, one of the largest groups so far reported, and we showed that the best predictor of cardiac events is the presence of a spontaneous abnormal ECG pattern associated with history of syncope. In the present article we will review the clinical characteristic of Brugada syndrome and point out a possible risk stratification scheme

INTRODUCTION: Inducibility of ventricular arrhythmias at programmed electrical stimulation (PES) ranges between 50% and 80% of patients with Brugada syndrome. However, the variety of PES protocols and the lack of data relative to a control group or to ventricular arrhythmia reproducibility contribute to a still undefined interpretation of PES outcome in Brugada syndrome. METHODS AND RESULTS: Twenty-one patients with Brugada syndrome (18 men and 3 women; mean age 34 years; 9/21 symptomatic; 8/21 with SCN5A gene mutation) underwent a PES protocol from two right ventricular sites. The endpoint was PES protocol completion or induction of sustained or reproducible (>6 consecutive inductions) nonsustained (>6 beats) fast ventricular arrhythmia. In 17 of 21 patients with Brugada syndrome, PES was repeated 2 months later to test ventricular arrhythmia reproducibility. Twenty-five healthy patients (17 men; mean age 36 years) formed the control group. In patients with Brugada syndrome, ventricular arrhythmia inducibility rate at PES was high (18/21 patients [85%]) and increased with protocol aggressiveness, independent of clinical presentation. In control subjects, no ventricular arrhythmias were induced. Among patients with Brugada syndrome, 14 (82%) of 17 patients remained inducible at a second PES. CONCLUSION: In our experience, ventricular arrhythmia inducibility in patients with Brugada syndrome, at variance with healthy controls, is high and does not correlate with clinical presentation. PES inducibility is deeply influenced by the protocol used. PES outcome is reproducible at a mid-term follow-up mainly if a categorical endpoint (inducible vs noninducible) is used. The need to assess the predictive value of specific PES protocols in targeted studies is widely emerging and is confirmed by our results

BACKGROUND: Mutations in the cardiac ryanodine receptor gene (RyR2) underlie catecholaminergic polymorphic ventricular tachycardia (CPVT), an inherited arrhythmogenic disease occurring in the structurally intact heart. The proportion of patients with CPVT carrying RyR2 mutations is unknown, and the clinical features of RyR2-CPVT as compared with nongenotyped CPVT are undefined. METHODS AND RESULTS: Patients with documented polymorphic ventricular arrhythmias occurring during physical or emotional stress with a normal heart entered the study. The clinical phenotype of the 30 probands and of 118 family members was evaluated, and mutation screening on the RyR2 gene was performed. Arrhythmias documented in probands were: 14 of 30 bidirectional ventricular tachycardia, 12 of 30 polymorphic ventricular tachycardia, and 4 of 30 catecholaminergic idiopathic ventricular fibrillation; RyR2 mutations were identified in 14 of 30 probands (36% bidirectional ventricular tachycardia, 58% polymorphic ventricular tachycardia, 50% catecholaminergic idiopathic ventricular fibrillation) and in 9 family members (4 silent gene carriers). Genotype-phenotype analysis showed that patients with RyR2 CPVT have events at a younger age than do patients with nongenotyped CPVT and that male sex is a risk factor for syncope in RyR2-CPVT (relative risk=4.2). CONCLUSIONS: CPVT is a clinically and genetically heterogeneous disease manifesting beyond pediatric age with a spectrum of polymorphic arrhythmias. beta-Blockers reduce arrhythmias, but in 30% of patients an implantable defibrillator may be required. Genetic analysis identifies two groups of patients: Patients with nongenotyped CPVT are predominantly women and become symptomatic later in life; patients with RyR2 CPVT become symptomatic earlier, and men are at higher risk of cardiac events. These data provide a rationale for prompt evaluation and treatment of young men with RyR2 mutations

AIMS: Differences in the sensitivity of the genotype of the congenital long QT syndrome to sympathetic stimulation have been suggested. This study compared the influence of sympathetic stimulation on continuous corrected QT (QTc) intervals between LQT1, LQT2 and LQT3 forms of the congenital long QT syndrome. METHODS AND RESULTS: We recorded a 12-lead electrocardiogram continuously before and after bolus injection (0.1 microg x kg(-1)) of epinephrine followed by continuous infusion (0.1 microg x kg(-1) min(-1)) in 12 LQT1, 10 LQT2, 6 LQT3, and 13 control patients. The QT intervals and previous RR intervals of all beats were measured semi-automatically, and the QTc intervals of all beats were calculated by Bazett's method. The dynamic response of the RR interval to epinephrine was no different between the four groups. The QTc was prolonged remarkably (477+/-42 to 631+/- 59 ms; P<0.0005, % delta prolongation =+32%) as the RR was maximally decreased (at peak of epinephrine), and remained prolonged at steady state conditions of epinephrine (556+/-56 ms; P<0.0005 vs baseline, +17%) in LQT1 patients. Epinephrine also prolonged the QTc dramatically (502+/-23 to 620+/-39 ms; P<0.0005, +24%) at peak of epinephrine in LQT2 patients, but this shortened to baseline levels at steady state (531+/-25 ms; P=ns vs baseline, +6%). The QTc was much less prolonged at peak of epinephrine in LQT3 (478+/-44 to 532+/-41 ms; P<0.05, +11%) and controls (394+/-21 to 456+/-18 ms; P<0.0005, +16%) than in LQT1 and LQT2 patients, and shortened to the baseline levels (LQT3; 466+/-49 ms, -3%, controls; 397+/-16 ms, +1%; P=ns vs baseline) at steady state. CONCLUSION: Our data suggest that the dynamic response of ventricular repolarization to sympathetic stimulation differs between LQT1, LQT2 and LQT3 syndromes, and may explain why the trigger of cardiac events differs between the genotypes

Pathogenesis of familial inherited arrhythmias is being progressively clarified thanks to the insights provided by molecular biology and by functional studies. Transmembrane or intracellular ion channel mutations have been identified in genetically determined forms of polymorphic ventricular tachycardia and sudden death such as catecholaminergic ventricular tachycardia, long QT syndrome, and Brugada syndrome. The role of molecular abnormalities in the genesis of monomorphic idiopathic ventricular tachycardias is less well defined, mainly because of the lack of a Mendelian pattern of inheritance. Interestingly, the presence of somatic mutations has been suggested as the mechanism for monomorphic ventricular tachycardia originating from the right ventricular outflow tract. The future goals for the application of molecular genetics to the management of cardiac arrhythmias will be to apply molecular genetics for a better risk stratification of affected individuals and to aim for the identification of gene-specific treatment of idiopathic ventricular tachycardia

BACKGROUND: Treatment of patients with Brugada syndrome is complicated by the incomplete information on the natural history of the disease related to the small number of cases reported. Furthermore, the value of programmed electrical stimulation (PES) for risk stratification is highly debated. The objective of this study was to search for novel parameters to identify patients at risk of sudden death. METHODS AND RESULTS: Clinical data were collected for 200 patients (152 men, 48 women; age, 41+/-18 years) and stored in a dedicated database. Genetic analysis was performed, and mutations on the SCN5A gene were identified in 28 of 130 probands and in 56 of 121 family members. The life-table method of Kaplan-Meier used to define the cardiac arrest-free interval in patients undergoing PES failed to demonstrate an association between PES inducibility and spontaneous occurrence of ventricular fibrillation. Multivariate Cox regression analysis showed that after adjusting for sex, family history of sudden death, and SCN5A mutations, the combined presence of a spontaneous ST-segment elevation in leads V1 through V3 and the history of syncope identifies subjects at risk of cardiac arrest (HR, 6.4; 95% CI, 1.9 to 21; P<0.002). CONCLUSIONS: The information on the natural history of patients obtained in this study allowed elaboration of a risk-stratification scheme to quantify the risk for sudden cardiac death and to target the use of the implantable cardioverter-defibrillator

The novel insights provided by the molecular genetic applied to the study of cardiac arrhythmias have just started to scratch the surface of the complex relationships between the genetic abnormalities of ion channel structure and the susceptibility to life threatening ventricular arrhythmias. These crucial pieces of information that are being gathered may have broader implications than those concerning the relatively restricted field of inherited arrhythmogenic diseases. An area of possible crucial application of the molecular genetic of cardiac ion channels, is the so-called drug-induced Torsade de Pointes (TdP) and acquired Long QT Syndrome. This condition is defined as an abnormal response to the administration of a variety of drugs which, in susceptible subjects, may induce an excessive QT interval prolongation and possibly lead to the onset of life-threatening ventricular tachyarrhythmias (drug-induced TdP). The 'proof of concept' that sub-clinical variants of the inherited long QT syndrome may play a causative role has been recently brought to light. However, large population-based studies are still needed in order to quantify the epidemiological relevance of such findings. The future developments in this area of research will lead to the availability of pre-prescription genotyping for the identification of the susceptible subjects and to the development of safer drugs

Molecular genetics applied to the study of inherited arrhythmogenic diseases has profoundly modified our understanding of cardiac electrophysiology providing new information on the crucial pathophysiological role of cardiac ion channels. These data are now putting forth innovative strategies for clinical management of the affected patients. Among these conditions, long QT syndrome (LQTS) was the first to enter the 'genetic era', and nowadays the availability of large population of patients with known mutation allows to draw meaningful genotype-phenotype correlation and genetic-based risk stratification. However, despite the remarkable impact on knowledge, several still poorly defined issues limit the translation of such information into more effective therapeutic stratigies. As an example, despite the evidence of a significant QT shortening potential, the gene-specific therapy of LQTS has still to prove its impact upon the risk of cardiac events. The present article reviews the most critical findings obtained in the last decade in the field of genetic of LQTS in the attempt of underlying its current applicability, limitations and the future perspectives of this knowledge in the management of affected patients

Although sudden infant death syndrome (SIDS) has been associated with long QT syndrome-a genetic disorder that causes arrhythmia-a causal link has not been shown. We screened genomic DNA from a child who died of SIDS and identified a de-novo mutation in KVLQT1, the gene most frequently associated with long QT syndrome. This mutation (C350T) had already been identified in an unrelated family that was affected by long QT syndrome. These results confirm the hypothesis that some deaths from SIDS are caused by long QT syndrome and support implementation of neonatal electrocardiographic screening